Recent advances in the development of agonists selective for beta1-type thyroid hormone receptor.

This mini-review will provide an overview on the recent design principles and structure-activity-relationship of beta-selective thyroid hormone receptor (TR) agonists. The prospects for the treatment of metabolic diseases as dyslipidemia with TRbeta-selective ligands are considerable enough so as to avoid cardiovascular acceleration mediated through TRalpha.

[The effect of K(ATP)-channel activation on the electrical stability of myocardium in rats with postinfarction cardiosclerosis]. / Vliianie aktivatsii K(ATP)-kanalov na élektricheskuiu stabil'nost' miokarda pri postinfarktnom kardioskleroze.

Opening of the ATP-dependent K-channels (K(ATP) channels) upon intravenous administration of the cardioselective activator BMS 180448 (3 mg/kg) decreased the ventricular fibrillation threshold (VFT) in rats with postinfarction cardiosclerosis (PIC). Preliminary injection of the selective K(ATP) channel blocker glibenclamide (0.3 mg/kg, i.v.) completely abolished the profibrillatory effect of BMS 180448. At the same time, the mitochondrial K(ATP) channel blocker 5-hydroxydecanoic acid (5 mg/kg) did not influence the proarrhythmogen activity of BMS 180448. Simultaneous administration of the sarcoK(ATP) channel inhibitor HMR 1098 (3 mg/kg) and BMS 180448 increased the VFT up to a level in intact animals. Administration of the mitoK(ATP) channel activator diazoxide (5 mg/kg) after preliminary treatment with guanethidine (50 mg/kg) increased the VFT in rats with PIC. It is concluded that opening of the mitoK(ATP) channels increases the cardiac electrical stability in rats with PIC.

[Changes in cardiac resistance to arrhythmogenic effects during ATP-dependent K+ channel activation]. / Izmenenie ustoichivosti serdtsa k aritmogennym vozdeistviiam v usloviiakh aktivatsii ATF-zavisimykh K+ kanalov.

It has been found that pretreatment with ATP-dependent potassium channel (KATP-channel) opener, BMS 180448 (3 mg/kg, intravenously), increases cardiac resistance against arrhythmogenic action of coronary artery occlusion and reperfusion in anaesthetized rats. However, BMS 180448 induced a decrease in ventricular fibrillation threshold in rats postinfarction cardiac fibrosis. This effect was completely abolished by administration of the KATP-channel inhibitor, glibenclamide. By contrast, coadministration of BMS 180448 and selective sarcolemmal KATP-channel inhibitor, HMR 1098, promoted an increase in ventricular fibrillation threshold in rats with postinfarction cardiac fibrosis before normal value. The selective mitochondrial KATP-channel opener, diazoxide, also exacerbated a decrease in ventricular fibrillation threshold induced by postinfarction cardiac sclerosis. But after depletion of endogenous catecholamine storage by pretreatment with guanthidine, diazoxide, on the contrary, elevated the ventricular fibrillation threshold. It has been suggested that stimulation of mitochondrial ATP-sensitive potassium channels promotes an elevation in electrical stability of the heart, whereas opening of sarcolemmal KATP-channel increases a possibility of ventricular arrhythmias.

Ifetroban sodium: an effective TxA2/PGH2 receptor antagonist.

This review presents a comprehensive discussion on the chemistry, pharmacokinetics, and pharmacodynamics of ifetroban sodium, a new thomboxane A2/prostaglandin H2 receptor antagonist. Thromboxane A2 is an arachidonic acid product, formed by the enzyme cyclooxygenase. In contrast to other cyclooxygenase products, thromboxane A2 has been shown to be involved in vascular contraction and has been implicated in platelet activation. In general, results of clinical studies and animal experiments indicate that hypertension is associated with hyperaggregability of platelets and increased thomboxane A2 levels in blood, urine, and tissues. The precursors to thromboxane A2, prostaglandin G2, and prostaglandin H2, also bind and activate the same receptors. Thus, a receptor antagonist was thought to be an improved strategy for reversing the actions of thromboxane A2/prostaglandin H2, rather than a thromboxane synthesis inhibitor. This review describes new methods for the synthesis and analysis of ifetroban, its tissue distribution, and its actions in a variety of animal models and disease states. We describe studies on the mechanisms of how ifetroban relaxes experimentally contracted isolated vascular tissue, and on the effects of ifetroban on myocardial ischemia, hypertension, stroke, thrombosis, and its effects on platelets. These experiments were conducted on several animal models, including dog, ferret, and rat, as well as on humans. Clinical studies are also described. These investigations show that ifetroban sodium is effective at reversing the effects of thromboxane A2- and prostaglandin H2-mediated processes.

Pharmacologic characterization of BMS-191095, a mitochondrial K(ATP) opener with no peripheral vasodilator or cardiac action potential shortening activity.

Previous work described ATP-sensitive K(+) channel (K(ATP)) openers (e.g., BMS-180448), which retain the cardioprotective activity of agents such as cromakalim while being significantly less potent as vasodilators. In this study, we describe the pharmacologic profile of BMS-191095, which is devoid of peripheral vasodilating activity while retaining glyburide-reversible cardioprotective activity. In isolated rat hearts subjected to 25 min of global ischemia and 30 min of reperfusion, BMS-191095 increased the time to onset of ischemic contracture with an EC(25) of 1.5 microM, which is comparable to 4.7 microM and 3.0 microM for cromakalim and BMS-180448, respectively. Comparisons of cardioprotective and vasorelaxant potencies in vitro and in vivo showed BMS-191095 to be significantly more selective for cardioprotection with virtually no effect on peripheral smooth muscle, whereas cromakalim showed little selectivity. In addition to increasing the time to the onset of contracture, BMS-191095 improved postischemic recovery of function and reduced lactate dehydrogenase release in the isolated rat hearts. The cardioprotective effects of BMS-191095 were abolished by glyburide and sodium 5-hydroxydecanoate (5-HD). BMS-191095 did not shorten action potential duration in normal or hypoxic myocardium within its cardioprotective concentration range nor did it activate sarcolemmal K(ATP) current (< or =30 microM). BMS-191095 opened cardiac mitochondrial K(ATP) with a K(1/2) of 83 nM, and this was abolished by glyburide and 5-HD. These results show that the cardioprotective effects of BMS-191095 are dissociated from peripheral vasodilator and cardiac sarcolemmal K(ATP) activation. Agents like BMS-191095 may owe their cardioprotective selectivity to selective mitochondrial K(ATP) activation.

The thyroid hormone receptor-beta-selective agonist GC-1 differentially affects plasma lipids and cardiac activity.

Thyroid hormones influence the function of many organs and mediate their diverse actions through two types of thyroid hormone receptors, TRalpha and TRbeta. Little is known about effects of ligands that preferentially interact with the two different TR subtypes. In the current study the comparison of the effects of the novel synthetic TRbeta-selective compound GC-1 with T3 at equimolar doses in hypothyroid mice revealed that GC-1 had better triglyceride-lowering and similar cholesterol-lowering effects than T3. T3, but not GC-1, increased heart rate and elevated messenger RNA levels coding for the I(f) channel (HCN2), a cardiac pacemaker that was decreased in hypothyroid mice. T3 had a larger positive inotropic effect than GC-1. T3, but not GC-1, normalized heart and body weights and messenger RNAs of myosin heavy chain alpha and beta and the sarcoplasmic reticulum adenosine triphosphatase (Serca2). Additional dose-response studies in hypercholesteremic rats confirmed the preferential effect of GC-1 on TRbeta-mediated parameters by showing a much higher potency to influence cholesterol and TSH than heart rate. The preferred accumulation of GC-1 in the liver vs. the heart probably also contributes to its marked lipid-lowering effect vs. the absent effect on heart rate. These data indicate that GC-1 could represent a prototype for new drugs for the treatment of high lipid levels or obesity.

The IF(1) inhibitor protein of the mitochondrial F(1)F(0)-ATPase.

Recent studies on the IF(1) inhibitor protein of the mitochondrial F(1)F(0)-ATPase from molecular biochemistry to possible pathophysiological roles are reviewed. The apparent mechanism of IF(1) inhibition of F(1)F(0)-ATPase activity and the biophysical conditions that influence IF(1) activity are summarized. The amino acid sequences of human, bovine, rat and murine IF(1) are compared and domains and residues implicated in IF(1) function examined. Defining the minimal inhibitory sequence of IF(1) and the role of conserved histidines and conformational changes using peptides or recombinant IF(1) is reviewed. Luft's disease, a mitochondrial myopathy where IF(1) is absent, is described with respect to IF(1) relevance to mitochondrial bioenergetics and clinical observations. The possible pathophysiological role of IF(1) in conserving ATP under conditions where cells experience oxygen deprivation (tumor growth, myocardial ischemia) is evaluated. Finally, studies attempting to correlate IF(1) activity to ATP conservation in myocardial ischemic preconditioning are compared.

ATP-Sensitive potassium channels: a review of their cardioprotective pharmacology.

ATP-sensitive potassium channels (K(ATP)) have been thought to be a mediator of cardioprotection for the last ten years. Significant progress has been made in learning the pharmacology of this channel as well as its molecular regulation with regard to cardioprotection. K(ATP)openers as a class protect ischemic/reperfused myocardium and appear to do so by conservation of energy. The reduced rate of ATP hydrolysis during ischemia exerted by these openers is not due to a cardioplegic effect and is independent of action potential shortening. Compounds have been synthesized which retain the cardioprotective effects of first generation K(ATP)openers, but are devoid of vasodilator and cardiac sarcolemmal potassium outward currents. These results suggest receptor or channel subtypes. Recent pharmacologic and molecular biology studies suggest the activation of mitochondrial K(ATP)as the relevant cardioprotective site. Implications of these results for future drug discovery and preconditioning are discussed.

Cardioselective antiischemic ATP-sensitive potassium channel (K(ATP)) openers. 6. Effect of modifications at C6 of benzopyranyl cyanoguanidines.

The effect on potency and selectivity of modifications at the C6 position of the cardioprotective K(ATP) opener BMS-180448 (2) is described. Structure-activity studies show that a variety of electron-withdrawing groups (ketone, sulfone, sulfonamide, etc.) are tolerated for cardioprotective activity as measured by EC(25) values for an increase in time to the onset of contracture in globally ischemic rat hearts. Changes made to the sulfonamido substituent indicate that compounds derived from secondary lipophilic amines are preferred for good cardioprotective potency and selectivity. The diisobutyl analogue 27 (EC(25) = 0.04 microM) is the most potent compound of this series. The cardiac selectivity of 27 results from a combination of reduced vasorelaxant potency and enhanced cardioprotective potency relative to the potent vasodilating K(ATP) openers (e.g., cromakalim). The diisobutylsulfonamide analogue 27 is over 4 orders of magnitude more cardiac selective than cromakalim (1). These results support the hypothesis that the cardioprotective and vasorelaxant properties of K(ATP) openers follow distinct structure-activity relationships. The mechanism of action of 27 appears to involve opening of the cardiac K(ATP) as its cardioprotective effects are abolished by the K(ATP) blocker glyburide.

Proarrhythmic effects of pinacidil are partially mediated through enhancement of catecholamine release in isolated perfused guinea-pig hearts.

The contribution of adrenergic stimulation to the proarrhythmic effects of pinacidil (30 microM), an opener of ATP-sensitive potassium channels (K+ATP), was tested in an isolated guinea-pig heart model of global ischemia (10 min) and reperfusion (10 min). None (0%) of the control hearts (n=10) elicited arrhythmias during ischemia or reperfusion. In the pinacidil-treated group, one heart (5%) experienced episodes of ventricular tachycardia (VT)/fibrillation (VF) during normoxia. During ischemia, 63% (12 out of 19) of pinacidil-treated hearts exhibited episodes of VT or VF. Hearts not in VT or VF (n=7) at the time of reperfusion, exhibited 71% VT and 43% VT/VF upon reperfusion. Proarrhythmic effects of pinacidil during ischemia or reperfusion were completely reversed by glyburide (n=9; 10 microM), a K+ATP antagonist, or nadolol (n=9; 3 microM), a beta-adrenergic antagonist. Isoproterenol (n=10; 50 nM), a beta-adrenergic agonist, induced a 20% incidence of ischemic VT and VF, and a 70% incidence of reperfusion VF, while methoxamine (n=10; 10 microM), an alpha-adrenergic agonist, demonstrated little proarrhythmia (20% VT/VF at reperfusion only). Proarrhythmic effects of isoproterenol were reversed by nadolol, but not glyburide. Pinacidil caused a slight potentiation of tachycardia induced by a bolus injection of tyramine (30 micro g), an indirectly acting sympathomimetic, but bolus injections of pinacidil (100 micro g) had no effect on heart rate. Nisoxetine, a catecholamine uptake 1 inhibitor, had no proarrhythmic effects when given alone. Catecholamine levels were reduced in pinacidil-treated hearts relative to vehicle-treated. In conclusion, it is suggested that the proarrhythmic effects of pinacidil following global ischemia and reperfusion in the isolated perfused guinea-pig heart appears to involve stimulation of beta-adrenoceptors. These proarrhythmic effects of pinacidil do not appear to be mediated solely through direct opening of K+ATP, but rather through an indirect enhancement of catecholamine release.

Preconditioning in rat hearts is independent of mitochondrial F1F0 ATPase inhibition.

Mitochondrial F1F0 adenosinetriphosphatase (ATPase) is responsible for the majority of ATP synthesis during normoxic conditions, but under ischemic conditions it accounts for significant ATP hydrolysis. A previous study showed that preconditioning in isolated rat hearts is mediated by inhibition of this ATPase during ischemia. We tested this hypothesis in our isolated rat heart model of preconditioning. Preconditioning was accomplished by three 5-min periods of global ischemia separated by 5 min of reperfusion. This was followed by 20 min of global ischemia and 30 min of reperfusion. Preconditioning significantly enhanced reperfusion contractile function and reduced lactate dehydrogenase release but paradoxically reduced the time to onset of contracture during global ischemia. Myocardial ATP was depleted at a faster rate during the prolonged ischemia in preconditioned than in sham-treated hearts, which is consistent with the reduced time to contracture. ATP during reperfusion was repleted more rapidly in preconditioned hearts, which is consistent with their enhanced contractile function. Preconditioning significantly reduced lactate accumulation during the prolonged ischemia. We were not able to demonstrate that mitochondrial F1F0 ATPase (measured in submitochondrial particles) was inhibited by preconditioning before or during the prolonged ischemia. The mitochondrial ATPase inhibitor oligomycin significantly conserved ATP during ischemia and increased the time to the onset of contracture, which is consistent with inhibition of the mitochondrial ATPase. Our results show that preconditioning in rat hearts can be independent of mitochondrial ATPase inhibition as well as ATP conservation.

Cardioprotective effect of diazoxide and its interaction with mitochondrial ATP-sensitive K+ channels. Possible mechanism of cardioprotection.

Previous studies showed a poor correlation between sarcolemmal K+ currents and cardioprotection for ATP-sensitive K+ channel (KATP) openers. Diazoxide is a weak cardiac sarcolemmal KATP opener, but it is a potent opener of mitochondrial KATP, making it a useful tool for determining the importance of this mitochondrial site. In reconstituted bovine heart KATP, diazoxide opened mitochondrial KATP with a K1/2 of 0.8 mumol/L while being 1000-fold less potent at opening sarcolemmal KATP. To compare cardioprotective potency, diazoxide or cromakalim was given to isolated rat hearts subjected to 25 minutes of global ischemia and 30 minutes of reperfusion. Diazoxide and cromakalim increased the time to onset of contracture with a similar potency (EC25, 11.0 and 8.8 mumol/L, respectively) and improved postischemic functional recovery in a glibenclamide (glyburide)-reversible manner. In addition, sodium 5-hydroxydecanoic acid completely abolished the protective effect of diazoxide. While-myocyte studies showed that diazoxide was significantly less potent than cromakalim in increasing sarcolemmal K+ currents. Diazoxide shortened ischemic action potential duration significantly less than cromakalim at equicardioprotective concentrations. We also determined the effects of cromakalim and diazoxide on reconstituted rat mitochondrial cardiac KATP activity. Cromakalim and diazoxide were both potent activators of K+ flux in this preparation (K1/2 values, 1.1 +/- 0.1 and 0.49 +/- 0.05 mumol/L, respectively). Both glibenclamide and sodium 5-hydroxydecanoic acid inhibited K+ flux through the diazoxide-opened mitochondrial KATP. The profile of activity of diazoxide (and perhaps KATP openers in general) suggests that they protect ischemic hearts in a manner that is consistent with an interaction with mitochondrial KATP.

Comparison of the protective effects of a highly selective ATP-sensitive potassium channel opener and ischemic preconditioning in isolated human atrial muscle.

The ATP-sensitive K+ channel (K[ATP] channel) has been implicated in the mechanism of ischemic preconditioning. We compared the protective effects of ischemic preconditioning and a highly selective K(ATP) channel opener, BMS 180448, in human myocardium. BMS 180448 was either used alone or in combination with the K(ATP) channel blocker glibenclamide. Human atrial trabeculae derived from the right atrial appendage were suspended in an organ bath, superfused with oxygenated Tyrode's solution at 37degrees C, and paced at 1 Hz. Experimental groups (n = 6 in each) were as follows: (1) control (C)--90 minutes hypoxic substrate-free perfusion at 3 Hz (simulated ischemia), followed by 120 minutes of reoxygenation with substrate at 1 Hz (reperfusion); (2) preconditioning (PC)--3 minutes simulated ischemia, 7 minutes reperfusion, followed by 90 minutes simulated ischemia and 120 minutes reperfusion; (3) BMS 180448 (BMS)--exposure to the drug for 5 minutes prior to 90 minutes simulated ischemia and 120 minutes reperfusion; (4) BMS 180448 + glibenclamide (BMS + G)--glibenclamide exposure for 10 minutes, and BMS for 5 minutes prior to 90 minutes simulated ischemia and 120 minutes reperfusion. Force of contraction prior to the commencement of the protocol was assigned the arbitrary value of 100%. Percentage recovery of contractile function at 120 minutes reperfusion was used as the endpoint. BMS (59.2 +/- 8.6%) and preconditioning (50.5 +/- 3.6% ) produced a similar degree of recovery of function at the end of 120 minutes of reperfusion; this was significantly different from the untreated control group (20.8 +/- 3.5%, p < 0.05, ANOVA). When glibenclamide was added prior to BMS, protection was lost (20.5 +/- 2.7%). In this human atrial preparation, a highly selective K(ATP) channel opener mimicked the protective effect of ischemic preconditioning. This protective effect of BMS was abolished by glibenclamide. These findings confirm that the mechanism of ischemic preconditioning in human muscle may be mediated via opening of the K(ATP) channel.

Pharmacology of ATP-sensitive potassium channel (KATP) openers in models of myocardial ischemia and reperfusion.

Recently, much interest has been focused on the pharmacology of ATP-sensitive potassium channels (KATP) in myocardial ischemia. KATP are thought to be involved with the mechanism of myocardial preconditioning, therefore further increasing the level of interest in these channels. Pharmacologic KATP openers have been shown by numerous investigators to protect ischemic-reperfused myocardium. These agents reduce necrosis, improve postischemic functional recovery, and inhibit contracture formation. These protective effects are abolished by KATP blockers. The cardioprotective effects of KATP openers are independent of vasodilator and cardiodepressant effects, but seem to be mediated by energy conservation (reduced ATP hydrolysis). Action potential shortening is also not correlated with cardioprotection, suggesting a role for intracellular (mitochondrial) KATP. Agents have been developed that retain the glyburide-reversible cardioprotective effects of cromakalim but are devoid of vasodilator and action potential shortening activity. Currently, studies are underway to determine the mechanism of cardioprotection. The potential role of mitochondrial KATP in the pathogenesis of ischemia is discussed in this review article.

Effect of timing of treatment of the glyburide-reversible cardioprotective activity of BMS-180448.

The effect of the timing of treatment with the ATP-regulated potassium channel agonist BMS-180448 was evaluated in isolated rat heart and ferret models of ischemia and reperfusion. In rat hearts, 10 microM BMS-180448, given before and after global ischemia as well as only during reflow, improved reperfusion contractile function and attenuated lactic dehydrogenase release, although reperfusion-only treatment was less effective. Cromakalim (10 microM) and bimakalim (10 microM) treatment before and after global ischemia afforded a degree of protection similar to that of BMS-180448, although they were not cardioprotective when given only during reperfusion. Pre- and post-treatment cardioprotection were abolished by glyburide. Ischemia/reperfusion significantly increased cytosolic calcium concentration ([Ca++]i) and BMS-180448 given only during reperfusion attenuated this change. In anesthetized ferrets, BMS-180448 (2 mg/kg) or vehicle was infused i.v. during a 40-min interval beginning 1) 10 min before coronary occlusion, 2) at the 45th min of ischemia or 3) at the 5th min of reperfusion. Preocclusion administration of BMS-180448 was associated with a 35% reduction in infarct damage from that recorded in vehicle-treated control ferrets. Drug administered at the midpoint of ischemia reduced infarct size approximately 44%, whereas delaying BMS-180448 infusion until the 5th min of reperfusion reduced, but still provided a significant (17%) level of salvage. The favorable effects of BMS-180448 in the ferret were not associated with changes in either collateral blood flow or peripheral hemodynamics. Thus BMS-180448 shows some protective effects when given only during reperfusion. Cromakalim and bimakalim did not exert similar actions and the difference may be secondary to the faster penetration of BMS-180448.

Adenosine A1 receptor blockade does not abolish the cardioprotective effects of the adenosine triphosphate-sensitive potassium channel opener bimakalim.

There has been controversy regarding whether ATP-sensitive potassium channel activation protects hearts through adenosine A1 receptor activation or the converse. We addressed this issue by determining the effect of the adenosine A1 receptor antagonist 8-cyclopentyl-1,3-dipropylxanthine (DPCPX) on the cardioprotective activity of the ATP-sensitive potassium channel opener bimakalim. In isolated rat hearts subjected to 25 min of global ischemia and 30 min of reperfusion, bimakalim significantly reduced lactate dehydrogenase release and improved postischemic recovery of contractile function. Bimakalim increased the time to the onset of ischemic contracture (EC25 = 1.2 microM), compared with vehicle, and 10 microM DPCPX had no effect on this protective action (EC25 = 1.1 microM). The 10 microM concentration of DPCPX was sufficient to abolish the bradycardic and cardioprotective effects of the adenosine A1 receptor agonist (R)-(-)-N6-(2-phenylisopropyl)adenosine. DPCPX alone had no effect on the severity of ischemia/reperfusion damage. Glyburide completely abolished the cardioprotective effects of bimakalim. Bimakalim (1 microg/kg, intracoronarily) given over four periods of 5 min, interspersed with 10-min drug-free periods, before a 60-min occlusion and 3-hr reperfusion significantly reduced infarction size in anesthetized dogs (25 +/- 5 and 8 +/- 2% of the left ventricular area at risk for vehicle- and bimakalim-treated groups, respectively). DPCPX had no effect on the infarction-sparing activity of bimakalim (9 +/- 3% of the left ventricular area at risk). The protective effect of bimakalim was not accompanied by marked hemodynamic changes or by changes in regional myocardial blood flow. The results of this study suggest that the cardioprotective effects of ATP-sensitive potassium channel openers are not dependent on adenosine A1 receptor activation in rat or dog models of ischemia.

Cardioselective antiischemic ATP-sensitive potassium channel (KATP) openers. 5. Identification of 4-(N-aryl)-substituted benzopyran derivatives with high selectivity.

This paper describes our studies aimed at the discovery of structurally distinct analogs of the cardioprotective KATP opener BMS-180448 (2) with improved selectivity for the ischemic myocardium. The starting compound 6, derived from the indole analog 4. showed good cardioprotective potency and excellent selectivity compared to 2 and the first-generation KATP opener cromakalim (1). The structure-activity studies indicate that increasing the size of the alkyl ester leads to diminished potency as does its replacement with a variety of other groups (nitrile, methyl sulfone). Replacement of the ethyl ester of 6 with an imidazole gave the best compound 3 (BMS-191095) of this series which maintains the potency and selectivity of its predecessor 6. The results described in this publication further support that there is no correlation between vasorelaxant and cardioprotective potencies of KATP openers. Compound 3 is over 20- and 4000-fold more selective for the ischemic myocardium than 2 and cromakalim (1), respectively. The selectivity for the ischemic myocardium is achieved by reduction of vasorelaxant potency rather than enhancement in antiischemic potency. As for cromakalim (1) and 2, the cardioprotective effects of compound 3 are inhibited by cotreatment with the KATP blocker glyburide, indicating that the KATP opening is involved in its mechanism of cardioprotection. With its good oral bioavailability (47%) and plasma elimination half-life (3 h) in rats, compound 3 offers an excellent candidate to investigate the role of residual vasorelaxant potency of 2 toward its cardioprotective activity in vivo.

Glyburide-reversible cardioprotective effects of BMS-180448: functional and energetic considerations.

Adenosine triphosphate (ATP)-sensitive potassium channel openers as a class exert cardioprotective effects, and we can separate vasodilator from glyburide-reversible cardioprotective activity in cromakalim analogs (e.g., BMS-180448). The purpose of this study was to determine the relation between cardiac function, energy status, and cardioprotective effects for BMS-180448 in isolated rat hearts compared with diltiazem. BMS-180448 (1-30 microM) or 0.1-1 microM diltiazem were given 10 min before 25-min global ischemia in rat hearts followed by 30 min of reperfusion. Both compounds significantly increased time to the onset of contracture during ischemia and improved postischemic recovery of contractile function in a concentration-dependent manner. At equivalent cardioprotective concentrations, BMS-180448 depressed preischemic cardiac function significantly less than did diltiazem. During ischemia, diltiazem significantly accelerated the functional decline observed in vehicle-treated hearts, whereas BMS-180448 attenuated the net rate of decline of function. Despite these different effects on preischemic and ischemic cardiac function, diltiazem and BMS-180448 conserved cardiac ATP during ischemia to a similar degree. BMS-180448 enhanced the recovery of ATP (also seen for diltiazem, but not to the same magnitude) and creatine phosphate during reperfusion compared with vehicle-treated hearts. For BMS-180448, this enhanced ATP recovery was accompanied by a significant improvement in the efficiency of oxygen use, which was profoundly reduced in reperfused vehicle-treated hearts. BMS-180448 also significantly enhanced the functional reserve after the 25-min period of global ischemia. Thus BMS-180448 protects ischemic myocardium and conserves ATP with less reduction in cardiac function compared with diltiazem.

Preconditioning is not abolished by the delayed rectifier K+ blocker dofetilide.

ATP-sensitive potassium channels are thought to play an important role in preconditioning. possibly due to shortening of the action potential duration (APD). The purpose of this study was to determine the effect of the class III antiarrhythmic agent dofetilide on preconditioning at a dose that abolishes APD shortening during ischemia A pilot study was performed to find a dose of dofetilide that would abolish the APD shortening effect of preconditioning Anesthetized dogs were subjected to 5-min coronary occlusion (or sham) and 10-min reperfusion followed by 60-min coronary occlusion. Monophasic action potentials were recorded periodically throughout the experiment. Significant APD shortening was observed during the 5- and 60-min ischemic periods, although preconditioning did not further enhance APD shortening during the prolonged ischemia. Dofetilide (1 mg/kg + 0.01 mg.kg-1.h-1 iv) abolished the APD shortening effect of ischemia. The effect of this dose of dofetilide on the protective action of preconditioning was then determined. Preconditioning significantly reduced infarct size expressed as a percentage of the area at risk compared with nonpreconditioned hearts. Dofetilide had no effect on infarct size when given to nonpreconditioned hearts. In addition, dofetilide did not alter the protective effect of preconditioning. No differences in collateral blood flow during ischemia were observed for any group. This study shows that the class III antiarrhythmic agent dofetilide does not abolish preconditioning and that the cardioprotective effect of preconditioning is independent of APD shortening below baseline values.